Yoshio Matsui mainly focuses on Crystallography, Condensed matter physics, Crystal structure, Electron diffraction and Superconductivity. His research integrates issues of Electron microscope and Transmission electron microscopy in his study of Crystallography. His Condensed matter physics study frequently draws connections between adjacent fields such as Magnetic field.
His studies deal with areas such as Powder diffraction, Diffraction, Multiferroics, Ion and Superlattice as well as Crystal structure. Yoshio Matsui interconnects Superstructure, Neutron diffraction, Nuclear magnetic resonance and Nanostructured materials in the investigation of issues within Electron diffraction. His biological study spans a wide range of topics, including Magnetization and Electrical resistivity and conductivity.
His main research concerns Crystallography, Condensed matter physics, Superconductivity, Transmission electron microscopy and Crystal structure. The Crystallography study combines topics in areas such as Electron diffraction, Phase and High-resolution transmission electron microscopy. Yoshio Matsui combines subjects such as Magnetic domain and Charge with his study of Condensed matter physics.
His Superconductivity research integrates issues from Magnetic susceptibility, Mineralogy and Electrical resistivity and conductivity. Yoshio Matsui has included themes like Microstructure and Analytical chemistry in his Transmission electron microscopy study. His study in Crystal structure is interdisciplinary in nature, drawing from both Cuprate, Electron microscope, Powder diffraction, Crystal and Superstructure.
Yoshio Matsui focuses on Condensed matter physics, Transmission electron microscopy, Crystallography, Manganite and Electron diffraction. The various areas that Yoshio Matsui examines in his Condensed matter physics study include Magnetic domain and Charge. His Transmission electron microscopy research also works with subjects such as
His work in Crystallography addresses subjects such as Magnetic moment, which are connected to disciplines such as Spinel and Magnetism. His Manganite research incorporates themes from Charge ordering, Phase and Optics. His Electron diffraction study integrates concerns from other disciplines, such as Phase transition, Magnetization, Powder diffraction and Crystal structure.
His primary areas of study are Condensed matter physics, Crystallography, Manganite, Skyrmion and Scanning transmission electron microscopy. His is doing research in Ferromagnetism and Spin, both of which are found in Condensed matter physics. The study incorporates disciplines such as Inorganic chemistry, Electron diffraction, Transmission electron microscopy and Magnetic moment in addition to Crystallography.
His Skyrmion research incorporates elements of Helicity, Magnetic skyrmion, Magnetic field and Current. His work carried out in the field of Magnetic skyrmion brings together such families of science as Current density and Orders of magnitude. His Scanning transmission electron microscopy research is multidisciplinary, relying on both Scanning confocal electron microscopy and High-resolution transmission electron microscopy.
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Real-space observation of a two-dimensional skyrmion crystal
X. Z. Yu;Y. Onose;N. Kanazawa;J. H. Park.
Near room-temperature formation of a skyrmion crystal in thin-films of the helimagnet FeGe
X. Z. Yu;N. Kanazawa;Y. Onose;K. Kimoto.
Nature Materials (2011)
Skyrmion flow near room temperature in an ultralow current density
X.Z. Yu;N. Kanazawa;W.Z. Zhang;T. Nagai.
Nature Communications (2012)
Magnetic and electronic properties in hole-doped manganese oxides with layered structures: La1-xSr1+xMnO4.
Y. Moritomo;Y. Tomioka;A. Asamitsu;Y. Tokura.
Physical Review B (1995)
Element-selective imaging of atomic columns in a crystal using STEM and EELS
Koji Kimoto;Toru Asaka;Takuro Nagai;Mitsuhiro Saito.
Electron microscopic observation of diamond particles grown from the vapour phase
Seiichiro Matsumoto;Yoshio Matsui.
Journal of Materials Science (1983)
Possible model of the modulated structure in high-Tcsuperconductor in a Bi-Sr-Ca-Cu-O system revealed by high-resolution electron microscopy
Yoshio Matsui;Hiroshi Maeda;Yoshiaki Tanaka;Shigeo Horiuchi.
Japanese Journal of Applied Physics (1988)
Towards control of the size and helicity of skyrmions in helimagnetic alloys by spin-orbit coupling
K. Shibata;X. Z. Yu;T. Hara;D. Morikawa.
Nature Nanotechnology (2013)
Magnetic stripes and skyrmions with helicity reversals
Xiuzhen Yu;Maxim Mostovoy;Yusuke Tokunaga;Weizhu Zhang.
Proceedings of the National Academy of Sciences of the United States of America (2012)
Real-Space Observation of Helical Spin Order
Masaya Uchida;Yoshinori Onose;Yoshio Matsui;Yoshinori Tokura;Yoshinori Tokura.
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